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An Illustrated Key to the Malacostraca (Crustacea) of the Northern Arabian Sea

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An Illustrated Key to the Malacostraca (Crustacea) of the Northern Arabian Sea An illustrated key to the Malacostraca (Crustacea) of the northern Arabian Sea. Part 1: Introduction Item Type article Authors Tirmizi, N.M.; Kazmi, Q.B. Download date 25/09/2021 13:22:23 Link to Item http://hdl.handle.net/1834/31867 Pakistan Journal of Marine Sciences, Vol.2(1), 49-66, 1993 AN IlLUSTRATED KEY TO THE MALACOSTRACA (CRUSTACEA) OF THE NORTHERN ARABIAN SEA Part 1: INTRODUCTION Nasima M. T:innizi and Quddusi B. Kazmi Marine Reference Collection and Resource Centre, University of Karachi Karachi-75270, Pakistan ABS'J.'R.ACT: The key deals with the Malacostraca from the northern Arabian Sea (22°09'N to 10°N and 50°E to 76°E). It is compiled from the specimens available to us and those which are in the literature. An introduction to the class Malacostraca and key to the identification of subclasses, superorders and orders is given. All the key characters are illustrated. Original references with later changes are men­ tioned. The key will be published in parts not necessarily in chronological order. KEY WORDS: Malacostraca -Arabian Sea - Orders -Keys. INTRODUCTION The origin of this work can be traced back to the prepartition era and the early efforts of carcinologists who reported on the marine Crustacea of the northern Arabi­ an Sea and adjacent oceanic zones. We owe indebtedness to many previous workers like Alcock (1896-1901) and Henderson (1893) who had also contributed to the list of species which the fauna now embodies. With the creation of Pakistan carcinological studies were 'undertaken specially by the students and scientists working at the Zoolo­ gy Department, University of Karachi. The progress was initially slow and restricted mostly to the description of species that could by obtained during random collections. However, several scientists got interested in the commercially important crustaceans and the work gained momentum. The systematic studies on organisms were encouraged by the specialists world around and as a result the Marine Reference Collection and Resource Centre (MRC) came into being. The reference library built up by exchange or donation basis from the areas adjacent to Pakistan led to the idea that our part of sea eventually may have the genera and species not yet been recorded. Further, inspired by the work of Lovett · (1981) a compiled guide was thus planned to accommodate all the malacostracan species recorded up to now from coasts, open sea or perhaps the deep sea. In all 735 species are treated in the key. Substantial part of this compilation was carefully scru­ tinized and improved by specialists in the world, some of them contributed additional information in the portion read by them. Their illustrations are used in the key with due permission. The present work is based on published papers, theses (Un.published) as well as the unidentified collections housed in the MRC or some other institutions. Species re­ ported in the literature but not available for study have been included as such since 50 Pakistan Journal of Marine Sciences, Vol.2(1), 1993 they are likely to turn up in future or may prove to have been extinct or migrated from the region. The work is heavily based on fresh collections made regularly by the staff of the Centre. Each collection is sorted, identified, illustrated and catalogued. New records or new species encountered are simultaneously prepared for publication in local or foreign journals. The work done so far is found only in publications that are not commonly available and several are now out of print. There appears to be a great need for such type of work both at home and abroad. The study aimed firstly, to bring together in a central reference, all the current taxonomic works on the Malacostraca of the northern Arabian Sea dealing with intertidal as well as offshore representatives and secondly to produce a guide that could readily be used by the students, biologists and informed amateurs. This is an attempt to pull together under one cover the published informa­ tion on the subject and the region in question. For researchers this key may open up a field for investigations and would give an idea as to the avenues in which further investigations can be directed. The present investigation began with the idea first to compile a list of known species of malacostracans from the northern Arabian Sea and coasts bounding it and then prepare keys for the identification of different malacostracan groups. It soon became apparent that systematic problems within the taxa pose insurmountable obstacles to the accomplishment of the proposed study. The search of references was a time consuming job, to obtain access was even more difficult task particularly from the west coast of India. The late arrival of some of the literature sought forced us to not to include those species, for the time being, in the already constructed key as inclusion of one species sometime disturbs the entire pattern. To overcome this problem name 11 11 of such species are given in the end of that group under the heading Not treated • The class Malacostraca, includes crabs, lobsters, crayfish, shrimps and pill bugs. Over 18,000 malacostracan species, accounting for about two-third of all known crus­ tacean species, have been described in the world. Tlie malacostracans have consider­ able economic importance. They provide more human food than all other inverte­ brate groups together. Small members of the class are a welcome part of the diet of many commercially valuable fishes. Malacostracans are generally large-sized crusta­ ceans, however, there is a considerable size variation. The smallest malacostracans are less than a millimeter long (Barth & Broshears, 1982) while an American lobster can extend 60cm and the world's largest living arthropod, the Japanese spider crab Macrocheira kaempferi, can measure 366cm in its chela span. The traditional systematics of the class Crustacea which was originated by Latreille (1806) divide it into the Entomostraca and Malacostraca, as known to all carcinolo­ gists. After that it had been clearly demonstrated that the Crustacea was more than a class and all the subclasses, including the subclass Malacostraca, begin to be consid­ ered as independent classes (Manton, 1977; Bowman & Abele, 1982; Scharm, 1982). In the present existing situation western authors like McLaughlin (1980) accept, with ·some changes, Crustacea as more than a class while Soviet carcinologists like Zaren­ kov (1982) accept a single class Crustacea with many subclasses. In 1988 again a Soviet taxonomist, Starobogatov proposed to divide the Crustacea as 4 independent classes, instead of 10 to 12 and agreed with Bowman & Abele (1982) in considering the Crustacea a supraclass ( =superclass of Bowman & Abele, 1982). The crustaceans Tirmizi and Kazmi: Key to the Northern Arabian Sea Malacostraca 51 TANAIDACEA ISOPODA ¥ CUMACEA SPELAEOGRIPHACEA ~ DECAPODA EUPHAUSIACEA AMPI-llONIDACEA ----~ Euca.rida -­ BATHYNELLACEA ANASPIDACEA Syncarida LEPTOSTRACA \, tNAHECARIS Phylloca.rida Malacostraca Maxillipoda I ...,<fP..,_..­ ? _,..... ~ p d ..... Gnathostraca CRUSTACEA Fig,l. Dendogram of the Malacostraca showing the possible relations of its orders to each other. (modified from various authors) have been divided into 6 classes by Bowman & Abele (1982)." A dendrogram is prepared showing evolutionary trend in the Malacostraca (Fig.l). It may be pointed out that Bowman & Abele (1982) divided the class Malacostraca into 3 subclasses. Their classification is basically similar to that of Moore & McCor­ mich (1969) but incorporating recent changes in the classification of certain taxa, for example in the unsettled classification of Decapoda, they have followed Glaessner (1969), Guinot (1977) and De Saint Laurent (1980 a,b). Later works by Abele & Felgenhauer (1986) have resulted in confirmation of the fundamental division of the decapods into two suborders i.e. Dendrobranchiata and Pleocyemata. Kim & Abele (1990) used nucleotide sequences in a phylogenetic study of selected decapods an.d provided molecular evidence in support of this division. Status of orders Cumacea 52 Pakistan Journal of Marine Sciences, Vol.2(1), 1993 and Tanaidacea are reviewed by Meglitsch & Schram (1991), they have put Cumacea and Tanaidacea as suborders of order Hemicaridea and orders Isopoda and Amphi­ poda under order Edriophthalma. The superorder Syncarida has been given the status of order and the two suborders Mysida and Lophogastrida of the order Mysida­ cea are ranked as orders. The order Decapoda has been divided into four suborders by these authors, they are Dendrobranchiata, Eukyphida, Euzygida and Reptantia. The scheme given by Bowman & Abele (1980) is followed here. The principal objective of the key is to contribute to the faunistic knowledge of the marine area, up to now little studied inspite of its oceanographic and fishery impor­ tance. According to Bacescu (1978) the calcareous and glauconiticous muddy bot­ toms of this area are ideal medium for generating special types of crustaceans, thus proving the In~an Ocean an important speciation centre. The present easy-to-follow illustrated key includes the extant and adult malacostra­ cans, free living and the parasitic ones collected and reported from the northern part of the Arabian Sea, its coastal boundaries as well as its islands of Laccadive, Scotra and Kuria Muria (Fig.2), from shores and inshores waters as well as pelagic and planktonic. Oceanographically the southern limit of the Arabian Sea could be fixed at 10° north latitude (Rao, 1979)~ This is strictly followed
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